植物生长发育中程序性细胞死亡

本文简要介绍了植物细胞凋亡的一些特点以及植物在营养生长和生殖生长过程中发生的细胞凋亡现象。指出细胞凋亡是植物生长发育过程中正常的生理现象。     

植物生长发育中程序性细胞死亡

本文简要介绍了植物细胞凋亡的一些特点以及植物在营养生长和生殖生长过程中发生的细胞凋亡现象。指出细胞凋亡是植物生长发育过程中正常的生理现象。     

植物细胞凋亡的研究进展

大量的实验研究表明细胞凋亡普遍存在于植物中,对于植物的正常生长发育及病理过程具有十分重要的生物学意义。植物细胞与动物细胞凋亡有许多相似的特征;在凋亡过程中有核酸内切酶的激活以及类caspase的参与;尽管植物细胞与动物细胞凋亡具有相似特征和机制,但其独特的分子调控机理目前尚不清楚 。     

植物细胞凋亡的研究进展

大量的实验研究表明细胞凋亡普遍存在于植物中,对于植物的正常生长发育及病理过程具有十分重要的生物学意义。植物细胞与动物细胞凋亡有许多相似的特征;在凋亡过程中有核酸内切酶的激活以及类caspase的参与。尽管植物细胞与动物细胞凋亡具有相似特征和机制,但其独特的分子调控机理目前尚不清楚。     

NO在植物中的调控作用

一氧化氮(NO)是一种易扩散的生物活性分子,是生物体内重要的信号分子.植物细胞通过NO合酶、硝酸还原酶、或非生化反应途径产生NO.NO参与植物生长发育调控和对生物与非生物环境胁迫的应答反应,大量证据表明NO是植物防御反应中的关键信使,其信号转导机制也受到越来越多的关注.本文主要通过讨论NO的产生、对植物生长周期的影响、在植物代谢中的信号调节以及参与细胞凋亡来阐述NO在植物中的作用.     

高等植物细胞凋亡的分子生物学研究

高等植物细胞凋亡 (ａｐｏｐｔｏｓｉｓ)是生物体生长发育、细胞分化及病理反应过程中细胞主动的、有序的死亡过程 ,是高等植物与环境及自身的新陈代谢过程中正常的生理反应[2 ,18-2 2 ,3 6] 。高等植物细胞凋亡又称程序性细胞死亡 (ｐｒｏ ｇｒａｍｍｅｄｃｅｌｌｄｅａｔｈ ,ＰＣＤ) ,是多细胞生物体中部分细胞在一定的病理或生理条件下 ,为维持内环境的稳定及适应生存环境而采取的一种由基因调控的主动死亡方式[6,8-16,3 0 ] 。由于ＰＣＤ的研究对于揭示高等植物生长发育及与环境相互作用机制和指导育种实践等方面有着重要而广泛的意义 ,…     

细胞凋亡及其对羊细胞影响研究进展

凋亡一般指机体细胞在生长发育过程中或在一定条件下,通过细胞内外因素调控下而发生的一种程序性细胞死亡.一般表现为单个细胞的死亡,且不伴有炎症反应.细胞凋亡与细胞增殖的动态平衡对维持多种细胞的正常功能存在着重要作用.机体通过细胞凋亡可清除多余、死亡、有害的细胞,保证机体的正常生长发育和生理功能,进而保证机体的健康.本研究简...     

可变剪接与细胞凋亡调控

细胞凋亡(apoptosis)是多细胞生物的一种基本生命活动,在机体的生长发育、免疫调节及维持内环境稳定等各方面扮演着重要的角色.遗传和生化研究表明,细胞凋亡受到复杂而精细的调控.转录水平、翻译后水平等各种层次的调控,构成了一个复杂的凋亡调控网络.     

NO在植物中的调控作用

一氧化氮（NO）是一种易扩散的生物活性分子,是生物体内重要的信号分子。植物细胞通过NO合酶、硝酸还原酶、或非生化反应途径产生NO。NO参与植物生长发育调控和对生物与非生物环境胁迫的应答反应,大量证据表明NO是植物防御反应中的关键信使,其信号转导机制也受到越来越多的关注。本文主要通过讨论NO的产生、对植物生长周期的影响、在植物代谢中的信号调节以及参与细胞凋亡来阐述NO在植物中的作用。     

植物管状分子发育中的细胞凋亡

细胞凋亡在植物发育过程和防御机制中发挥着重要作用.植物细胞凋亡具有染色质固缩和边缘化、DNA片断化、核的降解、质膜内缩、大量囊泡的出现、细胞壁的修饰等特征,是由相关的基因、蛋白酶以及细胞色素C介导和调控的.本文根据国内外的研究报道,对两种管状分子(导管、筛管)发育过程中细胞凋亡的形态学变化以及机制进行分析,为进一步探讨细胞凋亡的途径和机制提供参考.     

Alpha-picolinic acid, a fungal toxin and mammal apoptosis-inducing agent, elicits hypersensitive-like response and enhances disease resistance in rice

Alpha-picolinic acid (PA), a metabolite of tryptophan and an inducer of apoptosis in the animal cell, has been reported to be a toxin produced by some of plant fungal pathogens and used in screening for disease resistant mutants. Here, we report that PA is an efficient apoptosis agent triggering cell death of hypersensitive-like response in planta. Confirmed by Fluorescence Activated Cell Sorter (FACS), rice suspension cells and leaves exhibited programmed cell death induced by PA. The PA-induced cell death was associated with the accumulation of reactive oxygen species that could be blocked by diphenylene iodonium chloride, indicating that the generation of reactive oxygen species was NADPHoxidase dependent. We also demonstrated the induction of rice defense-related genes and subsequent resistant enhancement by PA against the rice blast fungus Magnaporthe grisea. Hence, it was concluded that the PA-stimulated defense response likely involves the onset of the hypersensitive response in rice, which also provides a simple eliciting tool for studying apoptosis in the plant cell.     

Effect of ethrel on apoptosis in carrot protoplasts

In recent years, apoptosis has been reported to exist in plants during normal development and in response to stress. However, little is known about the relation of hormones to this form of programmed cell death. Here, we report examination of characteristics of apoptosis in carrot protoplasts induced by ethylene evolved from ethrel (2-chloroethylphosphonic acid). Nucleus condensation and DNA ladders were observed, and neutral comet assay, which detects DNA cleavage, also provided evidence that ethrel treatment resulted in nuclear DNA fragmentation. Strikingly, a close correlation between the incidence of DNA comets and the percentage of apoptotic protoplasts was shown in ethrel-treated carrot protoplasts. In conclusion, this study demonstrated that ethylene is an active inducer of apoptosis in carrot protoplasts, and that ethylene-induced plant cell death showed characteristics similar to those of apoptosis in animals.     

Different cell cycle modifications repress apoptosis at different steps independent of developmental signaling in Drosophila

Apoptotic cell death is important for the normal development of a variety of organisms. Apoptosis is also a response to DNA damage and an important barrier to oncogenesis. The apoptotic response to DNA damage is dampened in specific cell types during development. Developmental signaling pathways can repress apoptosis, and reduced cell proliferation also correlates with a lower apoptotic response. However, because developmental signaling regulates both cell proliferation and apoptosis, the relative contribution of cell division to the apoptotic response has been hard to discern in vivo. Here we use Drosophila oogenesis as an in vivo model system to determine the extent to which cell proliferation influences the apoptotic response to DNA damage. We find that different types of cell cycle modifications are sufficient to repress the apoptotic response to ionizing radiation independent of developmental signaling. The step(s) at which the apoptosis pathway was repressed depended on the type of cell cycle modification—either upstream or downstream of expression of the p53-regulated proapoptotic genes. Our findings have important implications for understanding the coordination of cell proliferation with the apoptotic response in development and disease, including cancer and the tissue-specific responses to radiation therapy.     

Genetically programmed cell death: the base of homeostasis and the form of the phytoimmunity response

Modern concepts of programmed cell death, particularly the apoptosis in animals and plants are analyzed in this paper. A comparative characteristic of apoptosis in animal and plant cells taking into consideration the physiologic features of cells is presented. Necrosis as a form of pathological and not genetically programmed cell death is characterized. The significance (necessity) of apoptosis during the formation of a plant’s hypersensitive response and the role of programmed cell death under conditions of joint interrelations in the “pathogen-host” system are discussed.     

Oxalic acid is an elicitor of plant programmed cell death during Sclerotinia sclerotiorum disease development

Accumulating evidence supports the idea that necrotrophic plant pathogens interact with their hosts by controlling cell death. Sclerotinia sclerotiorum is a necrotrophic ascomycete fungus with a broad host range (>400 species). Previously, we established that oxalic acid (OA) is an important pathogenicity determinant of this fungus. In this report, we describe a mechanism by which oxalate contributes to the pathogenic success of this fungus; namely, that OA induces a programmed cell death (PCD) response in plant tissue that is required for disease development. This response exhibits features associated with mammalian apoptosis, including DNA laddering and TUNEL reactive cells. Fungal mutants deficient in OA production are nonpathogenic, and apoptotic-like characteristics are not observed following plant inoculation. The induction of PCD by OA is independent of the pH-reducing abilities of this organic acid, which is required for sclerotial development. Moreover, oxalate also induces increased reactive oxygen species (ROS) levels in the plant, which correlate to PCD. When ROS induction is inhibited, apoptotic-like cell death induced by OA does not occur. Taken together, we show that Sclerotinia spp.-secreted OA is an elicitor of PCD in plants and is responsible for induction of apoptotic-like features in the plant during disease development. This PCD is essential for fungal pathogenicity and involves ROS. Thus, OA appears to function by triggering in the plant pathways responsible for PCD. Further, OA secretion by Sclerotinia spp. is not directly toxic but, more subtly, may function as a signaling molecule.     

Vacuolar processing enzyme: an executor of plant cell death

Apoptotic cell death in animals is regulated by cysteine proteinases called caspases. Recently, vacuolar processing enzyme (VPE) was identified as a plant caspase. VPE deficiency prevents cell death during hypersensitive response and cell death of limited cell layers at the early stage of embryogenesis. Because plants do not have macrophages, dying cells must degrade their materials by themselves. VPE plays an essential role in the regulation of the lytic system of plants during the processes of defense and development. VPE is localized in the vacuoles, unlike animal caspases, which are localized in the cytosol. Thus, plants might have evolved a regulated cellular suicide strategy that, unlike animal apoptosis, is mediated by VPE and the vacuoles.     

Regulation of T cell apoptosis during the immune response

Apoptosis of T-lymphocytes is a fundamental process regulating antigen receptor repertoire selection during T cell maturation and homeostasis of the immune system. It also plays a key role in elimination of autoreactive lymphocytes. Resting mature T cells are activated by antigen to elicit an appropriate immune response. In contrast, preactivated T cells undergo activation-induced cell death (AICD) in response to TCR triggering alone. Thus, death by apoptosis is essential for function, growth and differentiation of T-lymphocytes. This review focuses on apoptosis mechanisms involved in T cell development and during the course of an immune response.     

Many ways to exit? Cell death categories in plants

Programmed cell death (PCD) is an integral part of plant development and defence. It occurs at all stages of the life cycle, from fertilization of the ovule to death of the whole plant. Without it, tall trees would probably not be possible and plants would more easily succumb to invading microorganisms. Here, we have attempted to categorize plant PCD in relation to three established morphological types of metazoan cell death: apoptosis, autophagy and non-lysosomal PCD. We conclude that (i) no examples of plant PCD conform to the apoptotic type, (ii) many examples of PCD during plant development agree with the autophagic type, and (iii) that other examples are apparently neither apoptotic nor autophagic.